Nervous system function relies on the polarized architecture of neurons, established by directional transport of pre- and postsynaptic cargoes. While delivery of postsynaptic components depends on the secretory pathway, the identity of the membrane compartment(s) that supply presynaptic active zone (AZ) and synaptic vesicle (SV) proteins is largely unknown. I will discuss our recent advances in our understanding of how key components of the presynaptic machinery for neurotransmitter release are transported and assembled focussing on our studies in genome-engineered human induced pluripotent stem cell-derived neurons. Specifically, I will focus on the composition and cell biological identity of the axonal transport vesicles that shuttle key components of neurotransmission to nascent synapses and on machinery for axonal transport and its control by signaling lipids. Our studies identify a crucial mechanism mediating the delivery of SV and active zone proteins to developing synapses and reveal connections to neurological disorders. In the second part of my talk, I will discuss how exocytosis and endocytosis are coupled to maintain presynaptic membrane homeostasis. I will present unpublished data regarding the role of membrane tension in the coupling of exocytosis and endocytosis at synapses. We have identified an endocytic BAR domain protein that is capable of sensing alterations in membrane tension caused by the exocytotic fusion of SVs to initiate compensatory endocytosis to restore plasma membrane area. Interference with this mechanism results in defects in the coupling of presynaptic exocytosis and SV recycling at human synapses.

Synaptic transmission provides the basis for neuronal communication. When an action-potential propagates through the axonal arbour, it activates voltage-gated Ca2+ channels located in the vicinity of release-ready synaptic vesicles docked at the presynaptic active zone. Ca2+ ions enter the presynaptic terminal and activate the vesicular Ca2+ sensor, thereby triggering neurotransmitter release. This whole process occurs on a timescale of a few milliseconds. In addition to fast, synchronous release, which keeps pace with action potentials, many synapses also exhibit delayed asynchronous release that persists for tens to hundreds of milliseconds. In this talk I will demonstrate how experimentally constrained computational modelling of underlying biological processes can complement laboratory studies (using electrophysiology and imaging techniques) and provide insights into the mechanisms of synaptic transmission.

Synapse formation during neuronal development is critical to establish neural circuits and a nervous system1. Every presynapse builds a core active zone structure where ion channels are clustered and synaptic vesicles are released2. While the composition of active zones is well characterized2,3, how active zone proteins assemble together and recruit synaptic release machinery during development is not clear. Here, we find core active zone scaffold proteins SYD-2/Liprin-α and ELKS-1 phase separate during an early stage of synapse development, and later mature into a solid structure. We directly test the in vivo function of phase separation with mutants specifically lacking this activity. These mutant SYD-2 and ELKS-1 proteins remain enriched at synapses, but are defective in active zone assembly and synapse function. The defects are rescued with the introduction of a phase separation motif from an unrelated protein. In vitro, we reconstitute the SYD-2 and ELKS-1 liquid phase scaffold and find it is competent to bind and incorporate downstream active zone components. The fluidity of SYD-2 and ELKS-1 condensates is critical for efficient mixing and incorporation of active zone components. These data reveal that a developmental liquid phase of scaffold molecules is essential for synaptic active zone assembly before maturation into a stable final structure.